Parallel self-associated structures formed by T,C-rich sequences at acidic pH.

Oligonucleotides of nonregular heteropyrimidine sequences incorporating or not incorporating purine residues 5'-d(ACTCCCTTCTCCTCTCTA), 5'-d(ACTCCCTGGTCCTCTCTA), 5'-d(TCTCTCCTGGTCCCTCC), and 5'-d(TCTCTCCTCTTCCCTCC) can form self-associated parallel-stranded (ps) structures at pH 4-5.5. The ps structures were identified by studying at neutral and acidic pH UV melting transitions, FTIR spectra, and fluorescence of pyrene-labeled oligonucleotides as well as by chemical joining of 5'-phosphorylated oligonucleotides. A gel electrophoresis run for oligonucleotides 5'-d(TCTCTCCTCTTCCCTCC) and 5'-d(ACTCCCTTCTCCTCTCTA) has shown the formation of homoduplexes at low DNA strand concentrations. Ps structures are held by C-C(+) base pairs and have N- and S-types of sugar puckering as detected by FTIR spectroscopy in the millimolar concentration range. Guanine inserts as well as thymine and purine inserts into an oligomeric cytosine sequence make the formation of the tetraplex i-motif unfavorable. MvaI restriction endonuclease, which recognizes the CCT/AGG sequence in DNA, does not cleave parallel pseudosubstrates.

DNA duplexes containing altered sugar residues as probes of EcoRII and MvaI endonuclease interactions with sugar-phosphate backbone.

Oligonucleotides containing 1-(beta-D-2'-deoxy-threo-pentofuranosyl)cytosine (dCx) and/or 1-(beta-D-2'-deoxy-threo-pentofuranosyl)thymine (dTx) in place of dC and dT residues in the EcoRII and MvaI recognition site CC(A/T)GG were synthesized in order to investigate specific recognition of the DNA sugar-phosphate backbone by EcoRII and MvaI restriction endonucleases. In 2'-deoxyxylosyl moieties of dCx and dTx, 3'-hydroxyl groups were inverted, which perturbs the related individual phosphates. Introduction of a single 2'-deoxyxylosyl moiety into a dC x dG pair resulted in a minor destabilization of double-stranded DNA structure. In the case of a dA x dT pair the effect of a 2'-deoxyxylose incorporation was much more pronounced. Multiple dCx modifications and their combination with dTx did not enhance the destabilization effect. Hydrolysis of dCx-containing DNA duplexes by EcoRII endonuclease was blocked and binding affinity was strongly depended on the location of an altered sugar. A DNA duplex containing a dTx residue was cleaved by the enzyme, but kcat/K(M) was slightly reduced. In contrast, MvaI endonuclease efficiently cleaved both types of sugar-altered substrate analogs. However it did not cleave conformationally perturbed scissile bonds, when the corresponding unmodified bonds were perfectly hydrolyzed in the same DNA duplexes. Based on these data the possible contributions of individual phosphates in the recognition site to substrate recognition and catalysis by EcoRII were proposed. We observed strikingly non-equivalent inputs for different phosphates with respect to their effect on EcoRII-DNA complex formation.

The Ecl18kI restriction-modification system: cloning, expression, properties of the purified enzymes.

Ecl18kI is a type II restriction-modification system isolated from Enterobacter cloaceae 18kI strain. Genes encoding Ecl18kI methyltransferase (M.Ecl18kI) and Ecl18kI restriction endonuclease (R.Ecl18kI) have been cloned and expressed in Escherichia coli. These enzymes recognize the 5'.../CCNGG...3' sequence in DNA; M.Ecl18kI methylates the C5 carbon atom of the inner dC residue and R.Ecl18kI cuts DNA as shown by the arrow. The restriction endonuclease and the methyltransferase were purified from E. coli B834 [p18Ap1] cells to near homogeneity. The restriction endonuclease is present in the solution as a tetramer, while the methyltransferase is a monomer. The interactions of M.Ecl18kI and R.Ecl18kI with 1,2-dideoxy-D-ribofuranose containing DNA duplexes were investigated. The target base flipping-out mechanism is applicable in the case of M.Ecl18kI. Correct cleavage of the abasic substrates by R.Ecl18kI is accompanied by non-canonical hydrolysis of the modified strand.

EcoRII endonuclease has two identical DNA-binding sites and cleaves one of two co-ordinated recognition sites in one catalytic event.

EcoRII is a typical restriction enzyme that cleaves DNA using a two-site mechanism. EcoRII endonuclease is unable to cleave DNA which contains a small number of EcoRII recognition sites but the enzyme activity can be stimulated in the presence of DNA with a high frequency of EcoRII sites. To investigate the mechanism of activation, the kinetics of stimulated EcoRII cleavage has been studied. A 14 bp substrate activated the cleavage of the 71 bp substrate, containing one EcoRII recognition site (trans-activation) by a competitive mechanism: the activator increased substrate binding but not catalysis. The activation increased if the substrate concentration decreased and if the activator had a lower affinity for the enzyme than the substrate. The introduction of the second recognition site into the 71 bp duplex also enabled cleavage of this substrate (cis-activation). Pyrophosphate bonds were incorporated into one of two recognition sites to switch off the cleavage of the phosphodiester bonds. Analysis of cleavage products of these modified substrates showed that EcoRII cuts one of two coordinated recognition sites in one catalytic event.

Use of UV spectroscopy for the study of nucleic acid cleavage by E. coli RNase H and restriction endonucleases.

A one-step spectrophotometric method for monitoring of nucleic acid cleavage by ribonuclease H from E. coli and type II restriction endonucleases has been proposed. It is based on recording of the increase in the UV absorbance at 260 nm during the course of enzymatic reaction. Duplexes stable under the reaction conditions were chosen as substrates for the enzymes being studied. In order to obtain duplex dissociation following their cleavage by the enzyme appreciate temperature conditions were selected. The spectrophotometric method may be applied for rapid testing of the nuclease activity in protein preparations as well as for precise quantitative analysis of nucleic acid degradation by enzymes. This method may be successfully employed in kinetic studies of nucleic acid-protein interactions.

The interaction of DNA duplexes containing 2-aminopurine with restriction endonucleases EcoRII and SsoII.

Oligonucleotides containing 2-aminopurine (2-AP) in place of G or A in the recognition site of EcoRII (CCT/AGG) or SsoII (CCNGG) restriction endonucleases have been synthesized in order to investigate the specific interaction of DNA with these enzymes. Physicochemical properties (CD spectra and melting behaviour) have shown that DNA duplexes containing 2-aminopurine exist largely in a stable B-like form. 2-Aminopurine base paired with cytidine, however, essentially influences the helix structure. The presence of a 2-AP-C mismatch strongly reduces the stability of the duplexes in comparison with the natural double strand, indicated by a biphasic melting behaviour. SsoII restriction endonuclease recognizes and cleaves the modified substrate with a 2-AP-T mismatch in the centre of the recognition site, but it does not cleave the duplexes containing 2-aminopurine in place of inner and outer G, or both. EcoRII restriction endonuclease does not cleave duplexes containing 2-aminopurine at all. The two-substrate mechanism of EcoRII-DNA interaction, however, allows hydrolysis of the duplex containing 2-aminopurine in place of adenine in the presence of the canonical substrate.

DNA duplexes containing methylated bases or non-nucleotide inserts in the recognition site are cleaved by restriction endonuclease R.EcoRII in presence of canonical substrate.

DNA duplexes containing the natural methylated bases N6-methyladenine (m6Ade), N4-methylcytosine (m4Cyt) or C5-methylcytosine (m5Cyt) in one strand of the recognition sequence are resistant to EcoRII restriction endonuclease (R.EcoRII). Hydrolysis of these modified duplexes was observed in the presence of the canonical substrate. Incorporation of m4Cyt or m5Cyt into both strands of the recognition sequence precludes such activation by a canonical substrate. R.EcoRII also fails to cleave substrate analogs in which one of the nucleosides in the recognition site is replaced by the 1,2-dideoxyribose (D) or by 1,3-propanediol (Prd) (modeling DNA with an abasic site). The hydrolysis of DNA duplexes with non-nucleotide inserts is also activated in the presence of canonical substrate. Thus, the two-substrate mechanism of EcoRII-DNA interaction allows hydrolysis of apurinic/apyrimidinic and hemimethylated DNA.

Two subunits of EcoRII restriction endonuclease interact with two DNA recognition sites.

The cleavage of a 14 base pair DNA duplex containing one EcoRII recognition site by EcoRII restriction endonuclease (R.EcoRII) was studied in single turnover experiments with varying enzyme concentrations in the micromolar range. The reaction rate increased with enzyme concentration until a ratio of one dimeric R.EcoRII enzyme to two double stranded oligonucleotide molecules. Excess of R.EcoRII lead to inhibition of cleavage. Maximum cleavage was also found with pBR322 DNA containing six EcoRII recognition sites at a ratio of one dimeric enzyme to two EcoRII recognition sites of the plasmid DNA. At higher ratios inhibition was observed. These observations indicate that the active enzyme complex is formed when two subunits of the enzyme interact with two R.EcoRII recognition sites.

Mechanism of the interaction of EcoRII restriction endonuclease with two recognition sites. Probing of modified DNA duplexes as activators of the enzyme.

The efficiency of cleavage of DNA duplexes with single EcoRII recognition sites by the EcoRII restriction endonuclease decreases with increasing substrate length. DNA duplexes of more than 215 bp are not effectively cleaved by this enzyme. Acceleration of the hydrolysis of long single-site substrates by EcoRII is observed in the presence of 11-14-bp substrates. The stimulation of hydrolysis depends on the length and concentration of the second substrate. To study the mechanism of EcoRII endonuclease stimulation, DNA duplexes with base analogs and modified internucleotide phosphate groups in the EcoRII site have been investigated as activators. These modified duplexes are cleaved by EcoRII enzyme with different efficiencies or are not cleaved at all. It has been discovered that the resistance of some of them can be overcome by incubation with a susceptible canonical substrate. The acceleration of cleavage of long single-site substrates depends on the type of modification of the activator. The modified DNA duplexes can activate EcoRII catalyzed hydrolysis if they can be cleaved by EcoRII themselves or in the presence of the second canonical substrate. It has been demonstrated that EcoRII endonuclease interacts in a cooperative way with two recognition sites in DNA. The cleavage of one of the recognition sites depends on the cleavage of the other. We suggest that the activator is not an allosteric effector but acts as a second substrate.

Cleavage of synthetic substrates containing non-nucleotide inserts by restriction endonucleases. Change in the cleavage specificity of endonuclease SsoII.

A study was made of the interaction between restriction endonucleases recognizing CCNGG (SsoII and ScrFI) or CCA/TGG (MvaI and EcoRII) DNA sequences and a set of synthetic substrates containing 1,3-propanediol, 1,2-dideoxy-D-ribofuranose or 9-[1'-hydroxy-2'-(hydroxymethyl)ethoxy] methylguanine (gIG) residues replacing either one of the central nucleosides or dG residues in the recognition site. The non-nucleotide inserts (except for gIG) introduced into the recognition site both increase the efficiency of SsoII and change its specificity. A cleavage at the noncanonical position takes place, in some cases in addition to the correct ones. Noncanonical hydrolysis by SsoII occurs at the phosphodiester bond adjacent to the point of modification towards the 5'-end. With the guanine base returned (the substrate with gIG), the correct cleavage position is restored. ScrFI specifically cleaves all the modified substrates. DNA duplexes with non-nucleotide inserts (except for the gIG-containing duplex) are resistant to hydrolysis by MvaI and EcoRII. Prompted by the data obtained we discuss the peculiarities of recognition by restriction endonucleases of 5-membered DNA sequences which have completely or partially degenerated central base pairs. It is suggested that SsoII forms a complex with DNA in an 'open' form.